Rockwell Automation SA3100 Distributed Power System Drv Config,Program User Manual

J-6

Drive Configuration and Programming

4.

Calculate the remainder of the necessary motor parameters using the following
measurements:

5.

Run the full algorithm with the parameters calculated above with flux loop and
access the table starting with the first point. The first point is the rated d-
component current I

d_rtd

. The value of this current must satisfy the following

inequality:

6.

If the inequality in #17 is true, then continue to access the table. If the inequality
(17) is not true then recalculate all the motor parameters with new I

d_rtd

and

rerun.

System architecture allows only three parameters to be saved.

L

s0

=

2 V

NL_rtd

V

2

mot _ rtd

(stator inductance)

( 10 )

I

d_rtd_1

(q - component voltage) ( 11 )

V

q_rtd

= OLR

.

I

q _ rtd _ 1

R

st _1

+

2

.

π

.

f

0

( 12 )

R

st_1

OLR

.

I

q _ rtd

_

1

V

d_rtd

_ 1

( 16 )

=

=

( 14 )

.

.

.

2

3

.

V

NL _ rtd

q - component voltage has to satisfy the following inequality:

2

3

.

V

mot _ rtd

V

q _ rtd

> 2

If the above inequality (12) is true then V

q_rtd

can be used for further calculations.

If the expression (12) is not true then the following assumption has to be set:

( 15 )

2

3

V

mot _ rtd

V

mot _ rtd

V

q_rtd

=

V

NL _ rtd

.

( 13 )

2.5

and stator resistance has to be recalculated using the follow equation:

2

3

(

)

2

3

2.5

.

Then d-component voltage and modified leakage inductance can be calculated:

2

3

.

V

2

q _ rtd _ 1

L*

σ

s 0

=

V

d _ rtd _ 1

+ I

d _ rtd _ 1

.

R

st _ 1

2

.

π

.

f

0

OLR

.

I

q _ rtd

_

1

.

( 17 )

I

d_rtd -

I

d _ rtd _ 1

I

d _ rtd

.

100% < 2%

( 18 )

●

stator time constant: T

st

=

L*

σ

s 0

R

st _ rtd

●

stator resistor: R

st _ rtd

●

magnetizing current:

I

z _ rtd